Matrix interpolation technique in the calculation of microstrip antenna impedance

In this letter, a method to determine the sampling inter¨als for the spline-type di¨ided-difference interpolation of spectral integrals is suggested by utilizing simple differentiation of the interpolating function. It impro¨es the numerical efficiency of the recent research based on the spline-type

Finite impulse response artificial neural network (FIR-ANN) is used for speeding up the FDTD. The FIR-ANN based FDTD (Neuro FDTD) is used to calculate input impedance of coaxial fed stacked microstrip patch antenna. Input impedance obtained by Neuro FDTD and FDTD are compared. It has been observed t

Existing methods to compute the bandwidth of probe-fed rectangular microstrip antenna elements are inaccurate for the range of substrate thicknesses considered for this research. When 0.0815h0 5 h (A0 is the free-space wacrelength and h is the substrate thickness) the effect of surface wacies is pre

Several formulas based on the cavity model and the transmission-line model are combined to produce closed-form expressions for calculating the bandwidth of probe-fed rectanguhr microstrip antenna elements with various thicknesses and various relatiue permittiuities of substrate materials. The formul

## Abstract The mathematical formulation of empirically developed formulas for the calculation of the resonant frequency of a thick‐substrate (h ≥ 0.08151λ~0~) microstrip antenna has been analyzed. With the use of tunnel‐based artificial neural networks (ANNs), the resonant frequency of antennas wi

The electric fields of the spatial Green's functions of microstrip structures are calculated by numerically integrating the Sommerfeld integrals along the Sommerfeld integration paths. To facilitate and accelerate con¨ergence, a higher order asymptotic extraction is made in the integrand. The electr